Objective:To observe the protective effect of ginkgo bilo ba extrac t (EGb 761), a free radical scavenger, on the photoreceptor cells after lighti nduced retinal damage. Methods:Seventytwo female SpragueDa wley (SD) rats we re randomly divided into 4 groups: normal control group, lightinduced retinal da m age model group, model+physiological saline group, and model+EGb 761 group, with 18 rats in each group. All of the rats except the ones in the control group were exposed to white light at (2740plusmn;120) lx for 6 hours after the dark adap tation for 24 hours to set up the lightinduced retinal damage model. Rats in m o del + physiological saline group and model+EGb 761 group were intraperitoneall y injected daily with physiological saline and 0.35% EGb 761 (100 mg/kg), respec tively 7 days before and 14 days after the light exposure. Apoptosis of photorec eptor cells was detected 4 days after light exposure; 7 and 14 days after light exposure, histopathological examination was performed and the layer number of ou ter nuclear layers (ONL) on the superior and inferior retina was counted. Results:Four days after light exposure, the apoptosis of photorecep tor cells was fou nd on ONL in model, model+ physiological saline and model+EGb 761 group, and w as obviously less in model + EGb 761 group than in model and model+physiologic al saline group. Seven days after light exposure, the layers of ONL on the super ior retina were 3 to 4 in model and model+physiological saline group, and 7 to 8 in model+EGb 761 group; the mean of the layer number of ONL in model+EGb 761 group (6.92plusmn;0.82) was less than that in normal control group (8.40plusmn;0.95) (t=-1.416, P<0.05), but significantly more than that in model (5.96 plusmn;1.36 ) and model+physiological saline group (5.90plusmn;1.40)(t=1.024, 1.084; P<0.05). Fourteen days after light exposure, the layers of ONL on the superior retina were 0 to 1 in model and model+physiological saline group, and 3 to 4 i n model+EGb 761 group. The mean of the layer number of ONL in model+EGb 761 group (5.5 2plusmn;1.06) was significantly more than that in model (3.44plusmn;2.15) and model + physiological saline group (3.37plusmn;1.91) (t=2.082, 2.146, P<0.05). Conclusion:EGb 761 can partially inhibit the apoptosis of pho toreceptor cells, thus exert protective effect on photoreceptor cells.
Objective To observe the degradation regulation of ubiquitinproteasome inhibitor nuclear factor kappa;B(NF-kappa;B)and its inhibitory signal protein Ikappa;B kinase in earlier period diabetic retinopathy(DR),and the effects on retinal ganglion cells (RGC) apoptosis.Methods Forty healthy adult Wistar rats were randomly divided into control (group A),DR(group B),DR+lowconcentration MG132 treated (group C)and DR+high concentration MG132 treated(group D)groups,10 rats in each group.After 6 and 8 weeks,the results of body masses and fasting blood glucose (FBG) were detected,the expression of NF-kappa;B and Ikappa;B were observed by immunohistochemistry respectively.RGC apoptosis was assessed by the terminal deoxynucleotidyl transferase mediated dUTP-biotin nick-end labelling (TUNEL) method.Results The expression of NF-kappa;B was upregulated in group B compared with group A,its expression decreased in group D compared with group B; but the expression of Ikappa;B was contrary to NF-kappa;B; RGC apoptosis was followed a similar pattern with the expression of NF-kappa;B; the differences among them were statistically significant (P<0.01).Compared the expression of NF-kappa;B,Ikappa;B and RGC apoptosis in group C and D, there were no statistically significant differences(P>0.05).Conclusion Ubiquitin-proteasome inhibitor MG132 can block the activation of NF-kappa;B,inhibit ubiquitination of Ikappa;B degradation and RGC apoptosis.
Objective To investigate the enhancing effect of ultrasound microbubbles on transfection of recombinant adenoassociated virus (rAAV) mediated green fluorecent protein (EGFP) gene into retinal ganglion cells (RGC) in vivo.Methods A total of 40 adult Sprague-Dawley (SD) rats were divided into four groups randomly (group A,B,C,D) with 10 rats in each. Group A was the normal control, in which the rats underwent intravitreal injection with 5 mu;l phosphate buffered solution. The rats in group B underwent intravitreal injection with 5 mu;l recombinant adenoassociated virus encoding EGFP gene (rAAV2-EGFP). The rats in group C underwent ultrasound irradiation on eyes right after intravitreal injection with 5 mu;l rAAV2-EGFP; The ultrasound irradiation was performed on the rats in group D right after intravitreal injection with the mixture solution of microbubbles and rAAV2-EGFP ultrasound. After 21 days, RGC were labeled retogradely with fluogold. Seven days after labeling, the retinal flatmounts and frozen sections were made from five rats in each group. Expression of EGFP reporter gene was observed by laser scanning confocal microscope and evaluated via average optical intensity (AOD) and RGC transfection rate. Labeled RGC were counted to evaluate the adverse effects.Results Green fluorescence can be observed exactly in labeled RGC in B,C,and D groups. The AOD and transfection rate in group D was (95.02plusmn;7.25)% and(20.10plusmn;0.74)% , respectively; which were higher than those in group B and C (F=25.970,25.799;P<0.01). The difference of the number of RGC among the four groups was not significant(F=0.877,P>0.05). Conclusion Under the condition of low frequency and with certain energy, ultrasoundmediated microbubble destruction can effectively and safely enhance rAAV delivery to RGC in rats.
Objective To establish a purified model of rat retinal ganglion cells (RGCs) cultured by serum-free medium,and provide a good cell model to investigate the damage of RGCs in glaucoma,retinal ischemia,and degenerative retinopathy. Methods Two monoclonal antibodies,anti-rat SIRP(OX-41)against rat macrophage and antibody against rat Thy-1(OX-7),were used to purify and characterize RGCs from 1-3-day old Sprague-Dawley(SD)rats by means of two-step filtration.Purified RGCs were cultured in serum-free neurobasal medium containing B27 and ciliary neurotrophic factor(CNTF) meeting the neuronal cellrsquo;s special requirements.Photomicrographs illustration,immunfluorescence staining of Thy-1,calcein-acetoxymethyl ester(calcein-AM)fluorescence images were used to observe and identify cultured retinal cells and purified RGCs. Results Among the primary cultured rat retinal cells,91% were retinal neurons.Protuberances of RGCs were seen after cultured for 24 hours.At the4th to 8th day,many cells had uniform configuration,large body,and long protuberances. At the 14th day,over 60% cells maintained viability.Immunoflurescence staining of Thy-1 showed the purity of RGCs was about 90%. The results of calcein-AM staining,which stained the living cells only,showed large cell body of RGCs and most of RGCs had a protuberance whose length was twice longer than the diameter of the cells. Conclusion RGCs cultured by serum-free medium has uniform size,good configuration,and high purity,which is adapt to the research of damage of RGCs caused by various factors and to evaluate the protective effects of neuroprotective agents. (Chin J Ocul Fundus Dis, 2006, 22: 200-203)
Objective To observe the protective effect on retinal ganglion cells (RGC) and the safety of intravitreal injected acteoside in rats. Methods A total of 50 male Sprague Dawley rats with the weight of 190-210 g were used in this study. Fifteen rats were used for safety experiment of intravitreal injection of acteoside. The rats were divided into group A, B, C, control group and blank group, three rats in each group. The rats in group A, B and C were received intravitreal injection of 5 mu;l acteoside at the concentration of 1, 2, and 5 mg/ml, respectively. Phosphate buffer solution (PBS) was injected in rats of control group. No treatment was performed for blank group. The retinal structure was examined by hematoxylin-eosin (HE) staining of retinal frozen sections at one, two and three weeks after injection. The retinal ultrastructure was examined by ultrathin section under transmission electron microscope at one and three weeks after injection. Others 35 rats were used for experiment of protective effect of acteoside on RGC. The rats were divided into operation group A and B (n=8), sham operation group C and D (n=8), and blank group (n=3). The optic nerve of rats in operation group was clamped for 10 seconds after optic nerve exposure, while the optic nerve of rats in sham operation group was exposed only. The rats in operation group A and B were received intravitreal injection with 5 mu;l acteoside (1 mg/ml) and 5 mu;l PBS respectively. The rats in sham operation group C and D were received intravitreal injection with 1 mu;l acteoside (1 mg/ml) and 1 mu;l PBS respectively. No treatment was performed for blank group. The retinal structure was examined by HE staining of retinal frozen sections at one, two and four weeks after injection. Immunohistochemistry was used to measure the expression of growth associated protein 43 (GAP-43). RGC apoptosis was assessed by the terminal deoxynucleotidyl transferase mediated dUTPbiotin nickend labelling (TUNEL) method. Software of SPSS 13.0 was used for the data statistical analysis in this study. Results In the safety experiment of intravitreal injected acteoside, there was no abnormity of cornea, anterior chamber, lens, vitreous cavity and retina after injection. At one, two and three weeks after injection, the retina structure was normal without significant apoptosis, necrosis and inflammatory cell infiltration. The ganglion cell layer showed slightly edema; there was no obvious change of retinal ultrastructure after injection of acteoside with 5 mg/ml and 2 mg/ml, but slight change with the format of 1 mg/ml. Transmission electron microscopy showed that intravitreal injection of 5 mu;l acteoside at the concentration of 2 or 5 mg/ml can induce significant changes of micro-structures of retina, while injections at 1mg/ml can only induce minor changes.In the experiment of protective effect of acteoside on RGC, light microscope revealed that the cell showed typical changes of apoptosis in operation group, but not in sham operation group and blank group. At the first and second week after injection, compared with the sham operation group and blank group, the RGC number was decreased in operation group. The difference of RGC numbers between operation group A and B was statistically different (F=26.206,P<0.05). The RGC numbers in operation group continues to decrease at the fourth week after injection, there was obvious difference compared with the first and second week after injection (F=17.364,P<0.05), but there was no difference of RGC numbers among sham operation intragroup and between sham operation group and blank group at all the time points. Immunohistochemistry showed that at the first week after injection, the integrated absorbance (IA) value in operation group was higher than that in other groups (F=33.466,P<0.05); there was no difference of IA value between operation group A and B. At the second week after injection,IA value in operation group A had slightly declined, but higher than that in operation group B (F=14.391,P<0.05). At the fourth week after injection,IA value in operation group A declined further, but also higher than that in other groups (F=4.178,P<0.05). TUNEL showed that on the first week after injection, RGC apoptosis rate in operation group was increased than that in other groups (F=15.365,P<0.05). At the second week after injection, RGC apoptosis rate in operation group was decreased, and it in operation group A was lower than that in operation group B (F=15.365,P<0.05). At the fourth week after injection, RGC apoptosis rate in operation group was decreased obviously, there was no difference compared with other groups (F=2.057,P>0.05). There was no difference of RGC apoptosis rate between sham operation group and blank group at all the time points. Conclusion Intravitreal injection of 5 mu;l acteoside (1 mg/ml) is safe for rat retina, and can upregulate GAP-43 expression and inhibit RGC apoptosis in optic nerve crush rats.
Objective To evaluate the inhibiting effect of adenosine on rat retinal ganglion cells (RGC) death induced by P2X7 and N-methyl-D-aspartate (NMDA) receptor. Methods (1) Long-Evan neonatal rats were back labeled with aminostilbamidine to identify RGC. The viability of RGC affected by P2X7 excitomotor BzATP (50 mu;mol/L), glutamate receptor excitomotor NMDA (100 mu;mol/L) and adenosine (300 mu;mol/L) was detected. (2) RGC from the retinae of unlabeled neonatal rats were cultured in vitro. After labeled with Fura-2 methyl acetate, an intracellular calcium indicator, the effect of BzATP, NMDA and adenosine on intracellular Ca2+ level was detected byCa2+ imaging system. Results Both BzATP (50 mu;mol/L) and NMDA(100 mu;mol/L) could kill about 30% of the RGC. Cell death was prevented by adenosine (300 mu;mol/L) with the cell viability increased from (68.9plusmn;2.3)% and (69.9plusmn;3.2)% to (91.2plusmn;3.5)% (P<0.001) and (102.1plusmn;3.9)% (P<0.001), respectively. BzATP (50 mu;mol/L) led to a large, sustained increase of intracellular Ca2+ concentration to (1183plusmn;109) nmol/L. After the adenosine intervened, Ca2+ concentration increased slightly to (314plusmn;64) nmol/L (P<0.001). Conclusion Adenosine may prevent RGC death and increase of intracellular Ca2+ concentration from P2X7and NMDA receptor stimulation. (Chin J Ocul Fundus Dis, 2007, 23: 133-136)
Objective To observe the protective effects of Na2SeO3 on the damage of retinal neuron induced by microwave. Methods Cultured fluids of retinal neuron were divided into 4 groups,including 1 group of control, according to the concentration of Na2SeO3 in cultured fluid and then exposed to 30 mW/cm2 microwave for 1 hour.The targets of lipid peroxidation and the concentration of selenium in cells were measured.Apoptosis detection was taken by TUNEL detection kit. Results The activity of SOD and GSH-Px rised,meanwhile the content of MDA and the amount of apoptosis cells decreased in 1times;107 mol/L group compared with the group without Na2SeO3.The other groups was superior in antioxdant capacity to 1times;107 mol/L group. Conclusion Na2SeO3 might be possessed of the effect of protecting the damage of retinal neuron induced by microwave. (Chin J Ocul Fundus Dis,2000,16:97-99)
Objective To observe the effect of shRNA interference lentivirus vector targeting rat Sirt1 gene on the expression of Sirt1 in retinal ganglion cell (RGC). Methods Four short hairpin (sh) RNA interference sequences targeting rat Sirt1 gene were designed. The target sequences of Oligo DNA were synthesized and annealed to double strand DNA, which was subsequently connected with pGLV3 lentivirus vector to build the lentiviral vector. The positive clones were identified by polymerase chain reaction (PCR) and DNA sequencing. The lentiviral vector construct and lentiviral packaging plasmids were co-transfected into 293T cells, then the titer of lentivirus were determined. The RGC were divided into 6 groups including blank group, negative control group and si-Sirt1-1, si-Sirt1-2, si-Sirt1-3, si-Sirt1-4 groups. Real-time PCR and Western blotting were used to detect the expression of Sirt1 mRNA and protein in the RGC cells. Results PCR and DNA sequencing analysis confirmed that the shRNA sequence was successfully inserted into the lentivirus vector. The concentrated titer of virus suspension was 8×108 TU/ml after the recombinant lentiviral vector successfully transfected and harvested in 293T cells. Comparing with NC group, the expression of Sirt1 mRNA and protein were significantly decreased in the si-Sirt1-1, si-Sirt1-2, si-Sirt1-3 and si-Sirt1-4 groups (F=27.682, 1 185.206; P=0.000, 0.000). The si-Sirt1-2 group had the strongest effect in reducing the expression of Sirt1 mRNA and protein. Conclusion The 4 lentiviral vectors harboring RNAi targeting rat Sirt1 gene can effectively down regulate the expression of Sirt1 mRNA and protein in RGC cells.
Objective To explore the effects of drugs on functions of mitochondria in retinal nerve cells, and to lay a foundation of the investigation of drug protection for retinal nerve cells. Methods Cultivation of the retinal nerve cells of 8 eyes of neonatal calves was performed. The changes of fluorescent density of the mitochondria of cultured cells labeled by dye rhodamine 123 (Rh123) before and after the activation of the medicines, including ferulic acid (FA), arginine, glycine,taurine, vitamine E and brain derived neurotrophic factor( BDNF) respectively, were detected by laser-scanning confocal microscopy. Results FA with the concentration of 500 μg/ml led the diphasic variation of the fluorescent intensity of mitochondria. After scanning for 60.772 seconds when treated with FA firstly, the fluorescent intensity decreased rapidly (from 45.425±4.153 to 22.135±5.293); while after 112.774 seconds when treated secondly, the in tensity increased obviously (from 19.655±4.383 to 28.247±4.764), and after 168.773 seconds when treated thirdly the intensity still increased. After scanning for 56.457 seconds when treated with vitamin E (12.5 mg/ml), the fluorescent in tensity increased obviously (from 88.255±5.039 to 111.273±4.529), which suggested that vitamin E with the concentration of 12.5 mg/ml strengthen the fluorescent intensity. After scanning for 58.147 and 134.148 seconds when treated with BDNF(50 ng/ml) respectively, the fluorescent intensity increased obviously (from 69.115±5.038 to 77.225±5.131) which suggested that BDNF with the concent ration of 50 ng/ml led the increase of the fluorescent intensity. Glycine (2.5 mg/ml) and arginine(30 mg/ml) didn’t affect the fluorescent intensity of mitochondria, and taurine (6.25 mg/ml) caused the appreciable decrease of the fluorescent intensity . Conclusion FA, BDNF and vitamin E may promote the metabolism of retinal nerve cells via the path of mitochondria, while amino acids may adjust the activation of retinal nerve cells through other ways. (Chin J Ocul Fundus Dis,2004,20:229-232)
Objective To observe the protective effect of ultrasound microbubble contrast agentmediated transfection of brain-derived neurotrophic factor(BDNF) into the retina and visual cortex on retinal ganglion cells (RGC) after optic nerve injury. Methods A total of 88 male Sprague-Dawley (SD) rats were randomly divided into normal group (group A, eight rats), sham operation group (group B, 16 rats), control group (group C, 16 rats), eyes transfection group (group D, 16 rats), brain transfection group (group E, 16 rats), combined transfection group (group F, 16 rats). The optic nerve crush injury was induced, and then the groups B to F were divided into one-week and two-week after optic nerve injury subgroup with eight rats each, respectively. The rats in group B and C underwent intravitreal and visual cortex injection with phosphate buffered solution respectively. The rats in group D and E underwent intravitreal and visual cortex injection with the mixture solution of microbubbles and BDNF plasmids respectively. The rats in group F underwent both intravitreal and visual cortex injection with the mixture solution of microbubbles and BDNF plasmids at the same time. The ultrasound exposure was performed on the rats in group D to F after injection with the mixture solution of microbubbles and BDNF plasmids. One and two weeks after optic nerve injury, RGC were retrogradely labeled with Fluorogold; active caspase-3 protein was observed by immunohistochemistry and the N95 amplitude was detected by pattern electroretinogram (PERG). Results Golden fluorescence can be observed exactly in labeled RGC in all groups,the difference of the number of RGC between the six groups and ten subgroups were significant(F=256.30,65.18;P<0.01). Active caspase-3 in ganglion cell layer was detected in group C to F, but not in group A and B. The difference of the N95 amplitude between the six groups and ten subgroups were significant(F=121.56,82.38;P<0.01).Conclusion Ultrasound microbubble contrast agent-mediated BDNF transfection to the rat retina and visual cortex can inhibit the RGC apoptosis after optic nerve injury and protect the visual function.